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Expression in Escherichia coli, purification and functional activity of recombinant human chaperonin 10
FEBS 15256
FEBS Letters 361 (1995) 211-214
Expression in Escherichia coli, purification and functional activity of recombinant human chaperonin 10 Giuseppe Legname*, Gianluca Fossati, Gianni Gromo, Nicoletta Monzini, Fabrizio Marcucci, Daniela Modena Italfarmaco Research Center, Via dei Lavoratori 54, 20092 Cinisello B., Milano, Italy
Received 19 January 1995: revised version received 14 February 1995
Abstract We have recently reported the cloning of a cDNA coding for a stress inducible human chaperonin 10. The protein was shown to possess 100% identity with the bovine homologue and a single amino acid replacement (glycine to serine at position 52) compared to rat chaperonin 10. Here we report the heteroiogous expression of human chaperonin 10 in Escherichia coil, its purification and its functional characterization. The recombinant protein was purified to homogeneity as judged by different analytical techniques, and mass spectrometry analysis showed a MW of 10,801 Da in agreement with the predicted sequence. This molecular weight accounts for a protein which is not modified post-translationally. In fact, natural rat chaperonin 10 has been shown to be acetylated at the N-terminus, a feature suggested to be important for targeting and functional activity. Here we show that recombinant human chaperonin 10 is fully active in assisting the chaperonin 60 GroEL in the refolding of denatured yeast enolase, thereby showing that, at least in the present system, post-translational acetylation is not necessary for its activity.
Recently, we have identified and cloned a cDNA encoding the human cpnl0 [10]. It showed a 100% homology with the bovine cpnl0 [11] and possessed a single amino acid substitution, serine in place of glycine at position 52, compared to rat cpnl0 [12]. A recent report has shown that human cpnl0 is identical to the early pregnancy factor (EPF) [13]. EPF has been known for long time to be involved in a number of physiological processes which are apparently unrelated to the role of cpnl0 in protein folding, but its characterisation has been elusive due to the difficulties encountered in its purification [13]. Here, we report the high-level expression of human cpnl0 in Escherichia coli. A single-step purification procedure enabled us to purify the protein to homogeneity and to characterise it by mass spectroscopy and N-terminal sequencing. The recombinant human cpn 10, which is not acetylated at the N-terminus residue, was fully functional in refolding experiments in vitro ere we employed GroEL as cpn60 and denatured yeast enolase as target protein.
Key words: Chaperonin 10; Human; GroES; GroEL; E. coli; Recombinant
2. Materials and methods
1. Introduction Molecular chaperons are proteins which facilitate correct iolding and assembly of nascent polypeptide chains in bacteria, Iungi, plants and animals [1,2] Members of this class of proteins ,~re the Escherichia coli heat shock proteins GroEL (heat shock !~rotein 60, HSP60) and GroES (HSP10), which have been ermed also chaperonins 60 and 10. The GroEL/GroES com~lex, which assists protein folding in a catalytic process requiring K ÷ and Mg-ATP [3], is the most studied chaperonin (cpn) -,ystem. In its native form, GroEL forms a double stacked ring, ~:ach ring comprising seven ---60 kDa subunits, while GroES is nade up of a single ring of seven = 10 kDa subunits. Both share a high degree of homology with prokaryotic and eukaryotic ~quivalents, suggesting a general mechanism in promoting proein folding [4]. Thus, GroES homologues have been identified in many :grokaryotes, plant chloroplasts and yeast, plant and mammalan mitochondria [5-9].
2.1. Materials Guanidine hydrochloride (GdnHC1) was purchased from Fluka. Enolase, 2-phosphoglyceric acid, nucleotides were obtained from Sigma. GroES and GroEL and restriction enzymes were obtained from Boehringer. All other reagents, at the highest degree of purity, were purchased from Merck and Fluka.
"Corresponding author. Department of Immunology, Italfarmaco Research Center, Via dei Lavoratori, 54-20092 Cinisello B., Vlilano, Italy. Fax: (39) (2) 6601 1579.
2.2. Cloning of human chaperonin 10 into E. coli expression vector pET-11d The total RNA extracted from heat shocked human hepatoma cell line HepG2 was amplified by reverse transcription-polimerase chain reaction (RT-PCR) using 2 l mer 5' and 18mer 3' oligonucleotidesof rat cpnl0 cDNA as primers [12]. In addition the primers included a Ncol and a BamHI sites suitable for cloning the PCR product into pET-I ld [14]. The complete sequences of the primers are 5"-GCGCGCGGATCCATGGCTGGACAAGCTTTTAGG-3' and 5'-GCGCGCAAGCTTGG ATCCTCAGTCGACATACTTTCC-3' for the human cpnl0 5' and 3' ends, respectively. The 5' end primer ?;col restriction site provided an ATG codon just upstream the GCA triplet that codes for the first residue of the native protein, an alanine. The T7 expression vector was obtained by cloning the NcoI and BamHI restriction fragment from the human cpnl0 cDNA into pET-1ld after digestion with NcoI and BamHI. The resulting plasmid coding for human cpnl0 was named pET-hucpnl0. The sequence analysis of the amplified product cloned into the expression vector was carried out with the Sequenase kit version 2.0 (United States Biochemical Co., Cleveland, OH, USA). The accession number of human chaperonin 10 is EMBL Ac. No. X75821.
Human cpnl0 gene corresponds to HSPE1 according to the Guidelines l'or Human Gene Terminology [Shows et al. (1987) Cytogenet. Cell Genet. 44, 11].
2.3. Expression of human cpnlO in E. coli Plasmid pET-hucpnl0 was transformed into BL21(DE3) pLysS. For expression, cells were grown at 37°C in ZBM9 medium supplemented
')014-5793/95159.50 © 1995 Federation of European Biochemical Societies. All rights reserved. ~ S D I 0014-5793(95)00184-0
212 with 50/.tg/ml of ampicillin and 34 pg/ml of chloramphenicol to an OD60o of 0.6-1. Isopropyl fl-D-thiogalactopyranoside was added to 0.4 mM, and cells were shaken for additional 3 h. The cells were harvested by centrifugation, resuspended in lysis buffer, 50 mM Tris-HC1, 2 mM EDTA, pH 8, at a concentration of 20 OD60o/ml and stored at -20°C until used. 2.4. Purification of recombinant human cpnlO Frozen cells were thawed at 4°C and sonicated over ice at an amplitude of 18/~m for 1 min intervals with 1 rain cooling for a total of 10 min. Cell sonicate was spun in a Sorvall (DuPont) GSA rotor at 5000 rpm for 10 min at 4°C to remove debris and intact cells. The supernatant was centrifuged at 55,000 × g in a TST 2817 rotor with a Kontron Centrikon T-1065 for 1 h at 4°C. The resulting pellet was resuspended in 5 M urea, 0.045% trifluoroacetic acid (TFA), centrifuged in a Sorvall GSA rotor at 4000 rpm for 10 min at 4°C and then dialysed against 2% acetonitrile, 0.1% TFA (buffer A) overnight. The sample was centrifuged again as before and filtered through an 0.45/lm filter before chromatographic purification. The human cpnl0 was then applied to a Vydac C18 reverse phase HPLC (RP-HPLC) column (10 × 300 mm) equilibrated in buffer A described above. Elution was carried out with a three-step gradient of acetonitrile containing 0.8% TFA: (1) from 0 to 32% in 91 min; (2) from 32 to 50% in 90 rain; and (3) from 50 to 80% in 30 min, at flow rate of 2.5 ml/min. Column effluent was monitored at A22o nm. The purified recombinant product was analysed by RPHPLC using an analytical Vydac C18 (4.6 × 150 mm) column using a linear gradient of buffer B from 0 to 55% of buffer B in 55 rain.
G. Legname et al./FEBS Letters 361 (1995) 211.-214 C-R4A CHROIIIATOPAC C H = I
2.6. Refolding assays Yeast enolase refolding assay was performed as previously described [15]. Briefly, yeast enolase (Sigma, 80 units/mg) was denatured in 4 M GdnHC1 at room temperature for at least 4 h and then diluted 60 fold into refolding buffer (50 mM Tris-HC1, pH 7.8, containing 10 mM Mg(CH3COO)2, 20 mM KCI, and 2 mM dithiothreitol, either with or without ADP 4 mM). GroEL, GroES and human ehaperonin 10 where added to the refolding buffer where stated. Refolding reaction were carried out at 25°C. The refolding mixture was diluted 25-fold into the assay buffer (50 mM Tris-HCl, pH 7.8, containing 1 mM 2-phosphoglyeeric acid and 1 mM MgCI2), and enolase activity was assayed at 240 nm monitoring the formation of phosphoenolpyruvate. 2. 7. Additional analytical techniques BCA protein assay reagent (Pierce) was utilised to determine protein content [16]. Sodium dodecyl sulfate-polyacrilamide gel electrophoresis (SDS-PAGE) was performed with a 8-25 polyacrylamide gradient gel using a Phast System instrument (Pharmacia) according to the Laemmli method [17]. Protein sequencing was performed by automated Edman degradation using an Applied Biosystem 475A instrument. Electron Spray Ionization-Mass Spectrometry (ESI-MS) was performed on a Finnigan MAT model 700 instrument.
3. Results RT-PCR amplification of total R N A from human hepatoma cell line HepG2, using the primers described in section 2, yielded a c D N A product of =300 bp (data not shown). The D N A was digested sequentially with NcoI and B a m H I and
CHRO~TOGRA~=2:HUCPNI.C02
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2.5. Binding of recombinant human cpnlO to GroEL Gel filtration experiments were performed using a Superose 6 FPLC column (Pharmacia) and the following eluent: 100 mM Tris-HCl, 10 mM KC1, 7 mM MgSO4, pH 7.8 containing 0.25 mM ATP. Prior to injection, samples of GroEL and either GroES or human chaperonin 10 were prepared in the above buffer supplemented with 0.6 mM ATP. Controls were made without addition of ATP. After 15 min incubation at room temperature samples were applied onto the column and peaks corresponding to GroEL and GroEL-cpn complex were collected manually and lyophilised. Lyophilized material was resuspended in 200 ,ul of water and proteins were precipitated by the addition of 800/A of cold acetone. After centrifugation precipitates were dissolved in SDS-buffer and analyzed by SDS-PAGE.
REPORTNo.-3
A n a l y s i s F i l e : I:HSPIOI.
I
** CALCULATION REPORT ** CH PKNO TIE AREA I i 18. 935 166137 6 35. 347 5829772
HEIGI'ff 8804 262181
5195909
270184
TOTAL
IIK
~
lifo
~ 3.1975 96.8025 100
Fig. 1. RP-HPLC analysis of recombinant human cpnl0 using a Vydac C18 column to assess purity of the protein (see section 2 for details).
cloned directly into pET-1 ld plasmid Ncol and B a m H I restriction sites in order to generate expression plasmid pET-hucpnl0. The recombinant plasmid was then inserted into E. coli strain BL21(DE3) pLysS for expression. S D S - P A G E analysis of induced total cell lysate indicated the presence of a band of =10 k D a present in the recombinant strain, but absent in a non-recombinant one (data not shown). Most of the recombinant protein was found in the pellet obtained after ultra centrifugation indicating that the product was insoluble. Therefore, the pellet was resuspended in 5 M urea containing 0.045% TFA. The resuspended pellet from 1 litre culture was dialysed overnight against 2% acetonitrile, 0.1% T F A and then applied onto a semi-preparative C18 Vydac R P - H P L C column where the recombinant human c p n l 0 was recovered as a single peak. Fig. 1 shows an analytical RPH P L C run with an aliquot of purified material, indicating a purity of the recombinant protein of >95%. Moreover, this preparation is not contaminated with detectable levels of G r o E S which shows a different mobility both in S D S - P A G E and R P - H P L C (data not shown). The estimated yields were about 10 mg of purified protein per litre of culture. Although the recombinant human cpnl 0 was originally found to be insoluble, after purification the lyophilised protein showed to be fully soluble in water. ESI-MS of the recombinant human c p n l 0 showed a molecular weight of the recombinant protein of 10801 Da as predicted from its deduced amino acid sequence lacking starting methionine (Fig. 2). N-terminal sequencing of the first 10 residues of the purified protein confirmed the expected sequence for the human cpn 10 [1 O] indicating again that
213
G Legname et al. IFEBS Letters 361 (1995) 211-214
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the initial methionine introduced during the amplification of ~ e c D N A was removed by E. coli [18]. The recombinant human cpnl0 was then tested for its ability 1o bind the E. coli cpn60 GroEL. Fig. 3 shows a silver-stained YiDS-PAGE analysis of peaks obtained after gel filtration ex?eriments. Upon addition of ATP to the incubation buffer the i~resence of a band corresponding to human cpnl0 was detect;~ble analysing the GroEL peak. The band was undetectable , ,mitting the nucleotide in the incubation buffer. We then tested ecombinant human cpnl0 in the refolding assay of yeast eno',ase. When yeast enolase is denatured with GdnHC1, its subse,luent spontaneous refolding can be arrested by the presence of t3roEL. GroES is required for enolase to be released from t3roEL in the presence of A D P [15]. In a similar manner, ecombinant human cpnl0 was capable to effectively release ~artially folded molecules of yeast enolase from GroEL (Fig. *). The above results also clearly indicate that the initial denatua t i o n of the recombinant protein and the subsequent RP:IPLC purification did not affect its functionality.
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Fig. 3. Silver stained 8 25% SDS-PAGE of GroEL peaks recovered by gel filtration. GroEL was pre incubated with recombinant human cpnl0 in the presence or absence of ATP (0.6 mM). Lane 1 shows the GroEL peak obtained without the addition of ATP; lane 2 shows the GroEL peak in the presence of ATE Lane 3 and 4 show pure recombinant human cpnl0 (Hu-cpnl0) and GroEL, respectively.
10 RefoldingTime(rain.)
~ 20
Fig. 4. Refolding profile of enolase in the presence of GroEL, GroES and ADP (open triangles) and in the presence of GroEL, recombinant human cpnl0 and ADP (closed squares). The negative control (open circles) is performed in the presence of GroEL and ADR The refolding was performed at 25°C, as described in section 2.
4. D i s c u s s i o n
Several eukaryotic cpn 10 have now been identified and characterised at the molecular level [6-9,19-20]. Common features of these molecules seem to be: (1) lack of any N-terminal presequence necessary for their targeting to the mitochondrial compartment; (2) removal of the starting methionine, followed by N-terminal acetylation of the first amino acid of the mature polypeptide; (3) capacity to bind to GroEL, in the presence of K + ions and Mg-ATP; and, consequently (4) the ability to replace GroES in in vitro assisted refolding experiments, using GroEL as cpn60. Conversely, however, GroES was not able to replace eukaryotic cpnl0 using mammalian cpn60 [21]. The first three features have been recently confirmed for pure natural human cpnl0 [13]. In addition, the complete primary structure of rat cpnl0 has been established [22], indicating again modification at the N-terminal amino acid. The authors of this report hypothesize that N-terminal acetylation could be important for the interaction with cpn60. In the present study we have been able to demonstrate that the recombinant form of human cpnl0, lacking N-terminal acetylation could still bind to a cpn60 and assist it in the folding of a denatured protein. Although it must be stressed that we employed an heterologous refolding system using E. coli GroEL as cpn60 and yeast enolase as the target for refolding, the present results suggest that N-terminal acetylation is dispensable for the functionality of eukaryotic cpnl0, at least as its role in protein refolding is concerned. These results extend those published in recent reports obtained using a C-terminal modified recombinant mouse cpnl0 [23] and a synthetic rat cpnl0 [24]. In light of recent findings suggesting that cpnl0 are multifunctional molecules one may also speculate that N-terminal acetylation could be relevant in functions other than assisting cpn60 in protein folding. Comparative studies of natural and recombinant cpnl0 in those biological systems that have been studied so far only with the natural form [13] may help clarify this issue. The availability of recombinant human cpnl0 will facilitate to address these studies.
214 References
[1] Gething, M.-J. and Sambrook, J. (1992) Nature 355, 33-45. [2] Hartl, F.-U., Hlodan, R. and Langer, T. (1994) Trends Biochem. Sci. 19, 20-25. [3] Viitanen, EV., Lubben, T.H., Reed, J., Goloubinoff, E, O'Keefe, D.E and Lorimer, G.H. (1990) Biochemistry 29, 5665-5671. [4] Martin, J., Mayhew, M., Langer, T. and Hartl, F.-H. (1994) Nature 366, 228-233. [5] Baird, EN., Hall, L.M.C. and Coates, A.R.M. (1988) Nucleic Acids Res. 16, 9047. [6] Ellis, R.J. (1990) Science 250, 954-959. [7] Rospert, S., Junne, T., Glick, B.S. and Schatz, G. (1993) FEBS Lett. 335, 358-360. [8] Burt, W.J.E., Leaver, C.J. (1994) FEBS Lett. 339, 139-140. [9] Lubben, T.H., Gatenby, A.A., Donaldson, G.K., Lorimer, G.H. and Viitanen, P.V. (1990) Proc. Natl. Acad. Sci. USA 87, 76837687. [10] Monzini, N., Legname, G., Marcucci, F., Gromo, G. and Modena, D. (1994) Biochim. Biophys. Acta 1218, 478-480. [11] Pilkington, S.J. and Walker, J.E. (1993) DNA Seq. 3, 291-295. [12] Ryan, M.T., Hoogenraad, N.J. and Hoj, P.B. (1994) FEBS Lett. 337, 152-156. [13] Cavanagh, A.C. and Morton, H. (1994) Eur. J. Biochem. 222, 551-560.
G. Legname et al./FEBS Letters 361 (1995) 211~14
[14] Studier, F.W.,Rosemberg, A.H., Dunn, J.J., and Dubendorff, J.W. (1990) Methods Enzymol. 185, 61-89. [15] Kubo, T., Mizobata, T. and Kawata, Y. (1993) J. Biol. Chem. 268, 19346-19351. [16] Smith, P.K., Krohn, R.I., Hermanson, G.T., Mallia, A.K., Gartner, F.H., Provenzano, M.D., Fujimoto, E.K., Goeke, N.M., Olson, B.J., and Klenk, D.C. (1985) Anal. Biochem. 150, 76-85. [17] Laemmli, U.K. (1970) Nature 227, 680-685. [18] Kendall, R.L., Yamada, R., and Bradshaw, R.A. (1990) Methods Enzymol. 185, 398-407. [19] Hartman, D.J., Hoogenraad, N.J., Condron, R. and H~j, EB. (1992) Proc. Natl. Acad. Sci. USA 89, 3394-3398. [20] Rospert, S., Glick, B.S., Jen6, E, Schatz, G., Todd, M.J., Lorimer, G.H. and Viitanen, P.V. (1993) Proc. Natl. Acad. Sci. USA 90, 10967-10971. [21] Viitanen, EN., Lorimer, G.H., Seetharam, R., Gupta, R.S., Oppenheim, J., Thomas, J.O. and Cowan, N.J. (1992) J. Biol. Chem. 267, 695-698. [22] Hartman, D.J., Hoogenraad, N.J., Condron, R. and Hoj, P.B. (1993) Biochim. Biophys. Acta 1164, 219-222. [23] Dickson, R., Larse, B., Viitanen, EV., Torney, M.B., Geske, J., Strange, R. and Bemis, L.T. (1994) J. Biol. Chem. 269, 2685826864. [24] Ball, H.L., Giuliani, E, Lucietto, E, Fossati, G. and Mascagni, E (1995) Biorned. Peptides, Proteins and Nucleic Acids (in press).
FEBS Letters 361 (1995) 211-214
Expression in Escherichia coli, purification and functional activity of recombinant human chaperonin 10 Giuseppe Legname*, Gianluca Fossati, Gianni Gromo, Nicoletta Monzini, Fabrizio Marcucci, Daniela Modena Italfarmaco Research Center, Via dei Lavoratori 54, 20092 Cinisello B., Milano, Italy
Received 19 January 1995: revised version received 14 February 1995
Abstract We have recently reported the cloning of a cDNA coding for a stress inducible human chaperonin 10. The protein was shown to possess 100% identity with the bovine homologue and a single amino acid replacement (glycine to serine at position 52) compared to rat chaperonin 10. Here we report the heteroiogous expression of human chaperonin 10 in Escherichia coil, its purification and its functional characterization. The recombinant protein was purified to homogeneity as judged by different analytical techniques, and mass spectrometry analysis showed a MW of 10,801 Da in agreement with the predicted sequence. This molecular weight accounts for a protein which is not modified post-translationally. In fact, natural rat chaperonin 10 has been shown to be acetylated at the N-terminus, a feature suggested to be important for targeting and functional activity. Here we show that recombinant human chaperonin 10 is fully active in assisting the chaperonin 60 GroEL in the refolding of denatured yeast enolase, thereby showing that, at least in the present system, post-translational acetylation is not necessary for its activity.
Recently, we have identified and cloned a cDNA encoding the human cpnl0 [10]. It showed a 100% homology with the bovine cpnl0 [11] and possessed a single amino acid substitution, serine in place of glycine at position 52, compared to rat cpnl0 [12]. A recent report has shown that human cpnl0 is identical to the early pregnancy factor (EPF) [13]. EPF has been known for long time to be involved in a number of physiological processes which are apparently unrelated to the role of cpnl0 in protein folding, but its characterisation has been elusive due to the difficulties encountered in its purification [13]. Here, we report the high-level expression of human cpnl0 in Escherichia coli. A single-step purification procedure enabled us to purify the protein to homogeneity and to characterise it by mass spectroscopy and N-terminal sequencing. The recombinant human cpn 10, which is not acetylated at the N-terminus residue, was fully functional in refolding experiments in vitro ere we employed GroEL as cpn60 and denatured yeast enolase as target protein.
Key words: Chaperonin 10; Human; GroES; GroEL; E. coli; Recombinant
2. Materials and methods
1. Introduction Molecular chaperons are proteins which facilitate correct iolding and assembly of nascent polypeptide chains in bacteria, Iungi, plants and animals [1,2] Members of this class of proteins ,~re the Escherichia coli heat shock proteins GroEL (heat shock !~rotein 60, HSP60) and GroES (HSP10), which have been ermed also chaperonins 60 and 10. The GroEL/GroES com~lex, which assists protein folding in a catalytic process requiring K ÷ and Mg-ATP [3], is the most studied chaperonin (cpn) -,ystem. In its native form, GroEL forms a double stacked ring, ~:ach ring comprising seven ---60 kDa subunits, while GroES is nade up of a single ring of seven = 10 kDa subunits. Both share a high degree of homology with prokaryotic and eukaryotic ~quivalents, suggesting a general mechanism in promoting proein folding [4]. Thus, GroES homologues have been identified in many :grokaryotes, plant chloroplasts and yeast, plant and mammalan mitochondria [5-9].
2.1. Materials Guanidine hydrochloride (GdnHC1) was purchased from Fluka. Enolase, 2-phosphoglyceric acid, nucleotides were obtained from Sigma. GroES and GroEL and restriction enzymes were obtained from Boehringer. All other reagents, at the highest degree of purity, were purchased from Merck and Fluka.
"Corresponding author. Department of Immunology, Italfarmaco Research Center, Via dei Lavoratori, 54-20092 Cinisello B., Vlilano, Italy. Fax: (39) (2) 6601 1579.
2.2. Cloning of human chaperonin 10 into E. coli expression vector pET-11d The total RNA extracted from heat shocked human hepatoma cell line HepG2 was amplified by reverse transcription-polimerase chain reaction (RT-PCR) using 2 l mer 5' and 18mer 3' oligonucleotidesof rat cpnl0 cDNA as primers [12]. In addition the primers included a Ncol and a BamHI sites suitable for cloning the PCR product into pET-I ld [14]. The complete sequences of the primers are 5"-GCGCGCGGATCCATGGCTGGACAAGCTTTTAGG-3' and 5'-GCGCGCAAGCTTGG ATCCTCAGTCGACATACTTTCC-3' for the human cpnl0 5' and 3' ends, respectively. The 5' end primer ?;col restriction site provided an ATG codon just upstream the GCA triplet that codes for the first residue of the native protein, an alanine. The T7 expression vector was obtained by cloning the NcoI and BamHI restriction fragment from the human cpnl0 cDNA into pET-1ld after digestion with NcoI and BamHI. The resulting plasmid coding for human cpnl0 was named pET-hucpnl0. The sequence analysis of the amplified product cloned into the expression vector was carried out with the Sequenase kit version 2.0 (United States Biochemical Co., Cleveland, OH, USA). The accession number of human chaperonin 10 is EMBL Ac. No. X75821.
Human cpnl0 gene corresponds to HSPE1 according to the Guidelines l'or Human Gene Terminology [Shows et al. (1987) Cytogenet. Cell Genet. 44, 11].
2.3. Expression of human cpnlO in E. coli Plasmid pET-hucpnl0 was transformed into BL21(DE3) pLysS. For expression, cells were grown at 37°C in ZBM9 medium supplemented
')014-5793/95159.50 © 1995 Federation of European Biochemical Societies. All rights reserved. ~ S D I 0014-5793(95)00184-0
212 with 50/.tg/ml of ampicillin and 34 pg/ml of chloramphenicol to an OD60o of 0.6-1. Isopropyl fl-D-thiogalactopyranoside was added to 0.4 mM, and cells were shaken for additional 3 h. The cells were harvested by centrifugation, resuspended in lysis buffer, 50 mM Tris-HC1, 2 mM EDTA, pH 8, at a concentration of 20 OD60o/ml and stored at -20°C until used. 2.4. Purification of recombinant human cpnlO Frozen cells were thawed at 4°C and sonicated over ice at an amplitude of 18/~m for 1 min intervals with 1 rain cooling for a total of 10 min. Cell sonicate was spun in a Sorvall (DuPont) GSA rotor at 5000 rpm for 10 min at 4°C to remove debris and intact cells. The supernatant was centrifuged at 55,000 × g in a TST 2817 rotor with a Kontron Centrikon T-1065 for 1 h at 4°C. The resulting pellet was resuspended in 5 M urea, 0.045% trifluoroacetic acid (TFA), centrifuged in a Sorvall GSA rotor at 4000 rpm for 10 min at 4°C and then dialysed against 2% acetonitrile, 0.1% TFA (buffer A) overnight. The sample was centrifuged again as before and filtered through an 0.45/lm filter before chromatographic purification. The human cpnl0 was then applied to a Vydac C18 reverse phase HPLC (RP-HPLC) column (10 × 300 mm) equilibrated in buffer A described above. Elution was carried out with a three-step gradient of acetonitrile containing 0.8% TFA: (1) from 0 to 32% in 91 min; (2) from 32 to 50% in 90 rain; and (3) from 50 to 80% in 30 min, at flow rate of 2.5 ml/min. Column effluent was monitored at A22o nm. The purified recombinant product was analysed by RPHPLC using an analytical Vydac C18 (4.6 × 150 mm) column using a linear gradient of buffer B from 0 to 55% of buffer B in 55 rain.
G. Legname et al./FEBS Letters 361 (1995) 211.-214 C-R4A CHROIIIATOPAC C H = I
2.6. Refolding assays Yeast enolase refolding assay was performed as previously described [15]. Briefly, yeast enolase (Sigma, 80 units/mg) was denatured in 4 M GdnHC1 at room temperature for at least 4 h and then diluted 60 fold into refolding buffer (50 mM Tris-HC1, pH 7.8, containing 10 mM Mg(CH3COO)2, 20 mM KCI, and 2 mM dithiothreitol, either with or without ADP 4 mM). GroEL, GroES and human ehaperonin 10 where added to the refolding buffer where stated. Refolding reaction were carried out at 25°C. The refolding mixture was diluted 25-fold into the assay buffer (50 mM Tris-HCl, pH 7.8, containing 1 mM 2-phosphoglyeeric acid and 1 mM MgCI2), and enolase activity was assayed at 240 nm monitoring the formation of phosphoenolpyruvate. 2. 7. Additional analytical techniques BCA protein assay reagent (Pierce) was utilised to determine protein content [16]. Sodium dodecyl sulfate-polyacrilamide gel electrophoresis (SDS-PAGE) was performed with a 8-25 polyacrylamide gradient gel using a Phast System instrument (Pharmacia) according to the Laemmli method [17]. Protein sequencing was performed by automated Edman degradation using an Applied Biosystem 475A instrument. Electron Spray Ionization-Mass Spectrometry (ESI-MS) was performed on a Finnigan MAT model 700 instrument.
3. Results RT-PCR amplification of total R N A from human hepatoma cell line HepG2, using the primers described in section 2, yielded a c D N A product of =300 bp (data not shown). The D N A was digested sequentially with NcoI and B a m H I and
CHRO~TOGRA~=2:HUCPNI.C02
Lamhda = 214nm ATT 9 C h a r t Speed 2, S u / m l n Flow HaePnlO lmi/ml Vydac C18 4 . 6 * 1 5 0 u A= ~ AcCN O. IS TFA IN WATER 8= 0.08~ TFA IN AcCN G/IADIENT= l~B PER M]N.
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2.5. Binding of recombinant human cpnlO to GroEL Gel filtration experiments were performed using a Superose 6 FPLC column (Pharmacia) and the following eluent: 100 mM Tris-HCl, 10 mM KC1, 7 mM MgSO4, pH 7.8 containing 0.25 mM ATP. Prior to injection, samples of GroEL and either GroES or human chaperonin 10 were prepared in the above buffer supplemented with 0.6 mM ATP. Controls were made without addition of ATP. After 15 min incubation at room temperature samples were applied onto the column and peaks corresponding to GroEL and GroEL-cpn complex were collected manually and lyophilised. Lyophilized material was resuspended in 200 ,ul of water and proteins were precipitated by the addition of 800/A of cold acetone. After centrifugation precipitates were dissolved in SDS-buffer and analyzed by SDS-PAGE.
REPORTNo.-3
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** CALCULATION REPORT ** CH PKNO TIE AREA I i 18. 935 166137 6 35. 347 5829772
HEIGI'ff 8804 262181
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TOTAL
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~ 3.1975 96.8025 100
Fig. 1. RP-HPLC analysis of recombinant human cpnl0 using a Vydac C18 column to assess purity of the protein (see section 2 for details).
cloned directly into pET-1 ld plasmid Ncol and B a m H I restriction sites in order to generate expression plasmid pET-hucpnl0. The recombinant plasmid was then inserted into E. coli strain BL21(DE3) pLysS for expression. S D S - P A G E analysis of induced total cell lysate indicated the presence of a band of =10 k D a present in the recombinant strain, but absent in a non-recombinant one (data not shown). Most of the recombinant protein was found in the pellet obtained after ultra centrifugation indicating that the product was insoluble. Therefore, the pellet was resuspended in 5 M urea containing 0.045% TFA. The resuspended pellet from 1 litre culture was dialysed overnight against 2% acetonitrile, 0.1% T F A and then applied onto a semi-preparative C18 Vydac R P - H P L C column where the recombinant human c p n l 0 was recovered as a single peak. Fig. 1 shows an analytical RPH P L C run with an aliquot of purified material, indicating a purity of the recombinant protein of >95%. Moreover, this preparation is not contaminated with detectable levels of G r o E S which shows a different mobility both in S D S - P A G E and R P - H P L C (data not shown). The estimated yields were about 10 mg of purified protein per litre of culture. Although the recombinant human cpnl 0 was originally found to be insoluble, after purification the lyophilised protein showed to be fully soluble in water. ESI-MS of the recombinant human c p n l 0 showed a molecular weight of the recombinant protein of 10801 Da as predicted from its deduced amino acid sequence lacking starting methionine (Fig. 2). N-terminal sequencing of the first 10 residues of the purified protein confirmed the expected sequence for the human cpn 10 [1 O] indicating again that
213
G Legname et al. IFEBS Letters 361 (1995) 211-214
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the initial methionine introduced during the amplification of ~ e c D N A was removed by E. coli [18]. The recombinant human cpnl0 was then tested for its ability 1o bind the E. coli cpn60 GroEL. Fig. 3 shows a silver-stained YiDS-PAGE analysis of peaks obtained after gel filtration ex?eriments. Upon addition of ATP to the incubation buffer the i~resence of a band corresponding to human cpnl0 was detect;~ble analysing the GroEL peak. The band was undetectable , ,mitting the nucleotide in the incubation buffer. We then tested ecombinant human cpnl0 in the refolding assay of yeast eno',ase. When yeast enolase is denatured with GdnHC1, its subse,luent spontaneous refolding can be arrested by the presence of t3roEL. GroES is required for enolase to be released from t3roEL in the presence of A D P [15]. In a similar manner, ecombinant human cpnl0 was capable to effectively release ~artially folded molecules of yeast enolase from GroEL (Fig. *). The above results also clearly indicate that the initial denatua t i o n of the recombinant protein and the subsequent RP:IPLC purification did not affect its functionality.
1
2
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Fig. 3. Silver stained 8 25% SDS-PAGE of GroEL peaks recovered by gel filtration. GroEL was pre incubated with recombinant human cpnl0 in the presence or absence of ATP (0.6 mM). Lane 1 shows the GroEL peak obtained without the addition of ATP; lane 2 shows the GroEL peak in the presence of ATE Lane 3 and 4 show pure recombinant human cpnl0 (Hu-cpnl0) and GroEL, respectively.
10 RefoldingTime(rain.)
~ 20
Fig. 4. Refolding profile of enolase in the presence of GroEL, GroES and ADP (open triangles) and in the presence of GroEL, recombinant human cpnl0 and ADP (closed squares). The negative control (open circles) is performed in the presence of GroEL and ADR The refolding was performed at 25°C, as described in section 2.
4. D i s c u s s i o n
Several eukaryotic cpn 10 have now been identified and characterised at the molecular level [6-9,19-20]. Common features of these molecules seem to be: (1) lack of any N-terminal presequence necessary for their targeting to the mitochondrial compartment; (2) removal of the starting methionine, followed by N-terminal acetylation of the first amino acid of the mature polypeptide; (3) capacity to bind to GroEL, in the presence of K + ions and Mg-ATP; and, consequently (4) the ability to replace GroES in in vitro assisted refolding experiments, using GroEL as cpn60. Conversely, however, GroES was not able to replace eukaryotic cpnl0 using mammalian cpn60 [21]. The first three features have been recently confirmed for pure natural human cpnl0 [13]. In addition, the complete primary structure of rat cpnl0 has been established [22], indicating again modification at the N-terminal amino acid. The authors of this report hypothesize that N-terminal acetylation could be important for the interaction with cpn60. In the present study we have been able to demonstrate that the recombinant form of human cpnl0, lacking N-terminal acetylation could still bind to a cpn60 and assist it in the folding of a denatured protein. Although it must be stressed that we employed an heterologous refolding system using E. coli GroEL as cpn60 and yeast enolase as the target for refolding, the present results suggest that N-terminal acetylation is dispensable for the functionality of eukaryotic cpnl0, at least as its role in protein refolding is concerned. These results extend those published in recent reports obtained using a C-terminal modified recombinant mouse cpnl0 [23] and a synthetic rat cpnl0 [24]. In light of recent findings suggesting that cpnl0 are multifunctional molecules one may also speculate that N-terminal acetylation could be relevant in functions other than assisting cpn60 in protein folding. Comparative studies of natural and recombinant cpnl0 in those biological systems that have been studied so far only with the natural form [13] may help clarify this issue. The availability of recombinant human cpnl0 will facilitate to address these studies.
214 References
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G. Legname et al./FEBS Letters 361 (1995) 211~14
[14] Studier, F.W.,Rosemberg, A.H., Dunn, J.J., and Dubendorff, J.W. (1990) Methods Enzymol. 185, 61-89. [15] Kubo, T., Mizobata, T. and Kawata, Y. (1993) J. Biol. Chem. 268, 19346-19351. [16] Smith, P.K., Krohn, R.I., Hermanson, G.T., Mallia, A.K., Gartner, F.H., Provenzano, M.D., Fujimoto, E.K., Goeke, N.M., Olson, B.J., and Klenk, D.C. (1985) Anal. Biochem. 150, 76-85. [17] Laemmli, U.K. (1970) Nature 227, 680-685. [18] Kendall, R.L., Yamada, R., and Bradshaw, R.A. (1990) Methods Enzymol. 185, 398-407. [19] Hartman, D.J., Hoogenraad, N.J., Condron, R. and H~j, EB. (1992) Proc. Natl. Acad. Sci. USA 89, 3394-3398. [20] Rospert, S., Glick, B.S., Jen6, E, Schatz, G., Todd, M.J., Lorimer, G.H. and Viitanen, P.V. (1993) Proc. Natl. Acad. Sci. USA 90, 10967-10971. [21] Viitanen, EN., Lorimer, G.H., Seetharam, R., Gupta, R.S., Oppenheim, J., Thomas, J.O. and Cowan, N.J. (1992) J. Biol. Chem. 267, 695-698. [22] Hartman, D.J., Hoogenraad, N.J., Condron, R. and Hoj, P.B. (1993) Biochim. Biophys. Acta 1164, 219-222. [23] Dickson, R., Larse, B., Viitanen, EV., Torney, M.B., Geske, J., Strange, R. and Bemis, L.T. (1994) J. Biol. Chem. 269, 2685826864. [24] Ball, H.L., Giuliani, E, Lucietto, E, Fossati, G. and Mascagni, E (1995) Biorned. Peptides, Proteins and Nucleic Acids (in press).